Influence of tube voltage on image quality in non-contrast photon-counting computed tomography of the head: Comparison of 120 kVp and 140 kVp

Abstract

Purpose

Non-contrast cerebral computed tomography (NCCT) is one of the most frequently performed CT examinations. Photon-counting CT (PCCT) offers advantages in terms of noise reduction, higher spatial resolution, and inherent spectral information. PCCT available today allows NCCT to be performed with tube voltage of 120 or 140 kVp. This study evaluates the impact of tube voltage on image quality at an equivalent dose.

Methods

76 patients with an NCCT with 120 kVp, 76 with 140 kVp, and 56 patients with slightly different effective tube current per group were included. Signal, noise, signal-to-noise ratio, gray–white contrast, and contrast-to-noise ratio were determined using several regions of interest for different virtual monoenergetic image (VMI) levels and compared between dose-equivalent groups. An image quality rating of the clinically used virtual monoenergetic images (VMIs) 65 keV was performed.

Results

The VMI 65 keV images at 120 kVp exhibited reduced noise, improved gray–white contrast, and improved contrast-to-noise ratio compared to 140 kVp (p < .001). The density differences between cortical gray matter at different distances from calvaria were also lower with 120 kVp (p < .001). The rating of image quality showed no difference between 120 kVp and 140 kVp.

Conclusions

Currently, NCCT with a tube voltage of 120 kVp versus 140 kVp seems to achieve better image quality. However, further studies are required to evaluate possible advantages of 140 kVp, for example artifact reduction in the case of dense foreign materials or enhanced spectral possibilities, and regarding imaging of special intracranial pathologies.

Keywords

Photon-counting computed tomography photon-counting detector tube voltage non-contrast CT of the head image quality

Get full access to this article

View all access options for this article.

References

Flohr

Schmidt

. Technical basics and clinical benefits of photon-counting CT. Investig Radiol 2023.

Sartoretti

Wildberger

Flohr

, et al. Photon-counting detector CT: early clinical experience review. Br J Radiol 2023; 96: 20220544.

Abel

Schubert

Winklhofer

. Advanced neuroimaging with photon-counting detector CT. Investig Radiol 2023; 58(7): 472–481.

Michael

Boriesosdick

Schoenbeck

, et al. Image-quality assessment of polyenergetic and virtual monoenergetic reconstructions of unenhanced CT scans of the head: initial experiences with the first photon-counting CT approved for clinical use. Diagnostics 2022; 12(2): 265.

Michael

Schoenbeck

Woeltjen

, et al. Nonenhanced photon counting CT of the head: impact of the keV level, iterative reconstruction and calvaria on image quality in monoenergetic images. Clin Neuroradiol 2023; 34: 1–9.

Pourmorteza

Symons

Reich

, et al. Photon-counting CT of the brain: in vivo human results and image-quality assessment. AJNR Am J Neuroradiol 2017; 38(12): 2257–2263.

Rajiah

Parakh

Kay

, et al. Update on multienergy CT: physics, principles, and applications. Radiographics 2020; 40(5): 1284–1308.

Albrecht

Vogl

Martin

, et al. Review of clinical applications for virtual monoenergetic dual-energy CT. Radiology 2019; 293(2): 260–271.

Schoenbeck

Sacha

Niehoff

, et al. Imaging of intracranial hemorrhage in photon counting computed tomography using virtual monoenergetic images. Neuroradiology 2024; 66: 729.

10.

Schoenbeck

Sacha

Niehoff

, et al. Imaging of hypodense gliotic lesions in photon counting computed tomography using virtual monoenergetic images. NeuroRadiol J 2024; 37: 19714009241240056.

11.

Symons

Reich

Bagheri

, et al. Photon-counting computed tomography for vascular imaging of the head and neck: first in vivo human results. Investig Radiol 2018; 53(3): 135–142.

12.

Lennartz

Laukamp

Neuhaus

, et al. Dual-layer detector CT of the head: initial experience in visualization of intracranial hemorrhage and hypodense brain lesions using virtual monoenergetic images. Eur J Radiol 2018; 108: 177–183.

13.

Rozeik

Kotterer

Preiss

, et al. Cranial CT artifacts and gantry angulation. J Comput Assist Tomogr 1991; 15(3): 381–386.

14.

Baker

Jr. Houser

. Computed tomography in the diagnosis of posterior fossa lesions. Radiol Clin 1976; 14(1): 129–147.

15.

Flohr

Petersilka

Henning

, et al. Photon-counting CT review. Phys Med 2020; 79: 126–136.

16.

Cala

Thickbroom

Black

, et al. Brain density and cerebrospinal fluid space size: CT of normal volunteers. AJNR Am J Neuroradiol 1981; 2(1): 41–47.